Stabilizing the Simple Hexagonal Structure -- Alloys of Tin

ORAL

Abstract

Approximately thirty elements have ground state or room-temperature structures with only one atom in the unit cell: fcc (Cu, Ir, Pb, etc.), bct (Cr, Ta, W, etc.), bct (In), rhombohedral (Hg), and even simple cubic (Po) lattices. The simple hexagonal (sh) lattice is never seen, even though it has a higher symmetry than rhombohedral and the same number of near neighbors as the bcc lattice. Only element, tin, has even a relatively low-energy sh structure.

Experimentally, the sh structure is found in mercury-tin alloys. To understand this, we performed a series of Density Functional calculations on HgxSn1-x and CdxSn1-x structures by the virtual crystal approximation (VCA); supercell calculations with ordered placement of the Cd/Hg atom (e.g., one impurity atom per unit cell); and using high-throughput AFLOW calculations to sample larger supercells with random impurities.

Both Cd and Hg stabilize the simple hexagonal structure against α- and β-Sn. The success of the VCA suggests that this is a density of states effect, and we examine the effect of alloying on the density of states using all of our techniques.

*MJ Mehl is funded by the Kinnear Foundation and Duke University. Duke University research is funded by the US Office of Naval Research grant N00014-17-1-2090.

Presenters

  • Michael Mehl

    • Physics, United States Naval Academy
    • United States Naval Academy
    • US Naval Academy

Authors

  • Michael Mehl

    • Physics, United States Naval Academy
    • United States Naval Academy
    • US Naval Academy

  • Mateo Ronquillo

    • United States Naval Academy

  • Corey Oses

    • Department of Mechanical Engineering and Materials Science, Duke University
    • Mechanical Engineering and Materials Science, Duke University
    • Center for Materials Genomics, Duke University
    • Duke University

  • Stefano Curtarolo

    • Materials Science, Electrical Engineering, Physics and Chemistry, Duke University
    • Mechanical Engineering and Materials Science, Duke University
    • Materials Science and Engineering, Center for Materials Genomics, Duke University, Durham, NC
    • Center for Materials Genomics, Duke University
    • Duke University
    • Department of Mechanical Engineering and Materials Science, Duke University
    • Materials Science, Electrical Engineering, Physics and Chemistry, Duke University, Durham, NC, USA

  • Cormac Toher

    • Department of Mechanical Engineering and Materials Science, Duke University
    • Mechanical Engineering and Materials Science, Duke University
    • Center for Materials Genomics, Duke University
    • Duke University